Oxidation of Benzyl Alcohol and Carbon Monoxide Using Gold Nanoparticles Supported on MnO<sub>2</sub> Nanowire Microspheres

Alhumaimess, Mosaed S.; Lin, Zhongjie; He, Qian; Lü, Li; Dimitratos, Nikolaos; Dummer, Nicholas F.; Conte, Marco; Taylor, Stuart H.; Bartley, Jonathan K.; Kiely, Christopher J.; Hutchings, Graham J.

doi:10.1002/chem.201303355

Cited by 43 publications

(23 citation statements)

References 61 publications

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“…The selection of support materials and preparation methods plays a key roles in determining the catalytic activity of supported noble metal catalysts. Transition metal oxides, such as Fe x O y , Co 3 O 4 ,, MnO x and TiO 2 , exhibit great potential as support materials for noble metal NPs due to their high chemical and thermal stabilities, wide abundance, and low cost . In addition, some oxides can further enhance the overall catalytic activity of the catalysts by enabling CO to react with the adsorbed oxygen species on their surface and the intermediate or oxygen provided by the support .…”

Section: Introductionmentioning

confidence: 99%

Gold‐Loaded Nanoporous Iron Oxide Cubes Derived from Prussian Blue as Carbon Monoxide Oxidation Catalyst at Room Temperature

et al. 2018

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This work reports the preparation of carbon monoxide (CO) oxidation catalysts based on gold nanoparticles supported on nanoporous iron oxide cubes. By heat-treating Prussian blue (PB) cubes at various temperatures between 250-450°C in air, nanoporous iron oxide cubes with surface areas up to 100 m 2 g À 1 are obtained. Owing to the relatively large surface area and nanoporous structure, the as-synthesized iron oxide cubes can be loaded with up to 11 wt% of Au nanoparticles without significant aggregation. When employed for CO oxidation, the Au-loaded nanoporous iron oxide cubes exhibit a high CO conversion rate of over 95% at room temperature under 0.1 L⋅min À 1 of CO gas flow, with specific activity of up to 1.79 mol CO ⋅g Au À 1 ⋅h À 1 . The high catalytic performance of the Au-loaded nanoporous iron oxide cubes for CO oxidation is contributed by various factors, including: (i) the high surface area of the iron oxide cubes which leads to the availability of more sites for the adsorption of oxygen molecules to react with carbon monoxide to generate more carbon dioxide (CO 2 ); (ii) the presence of nanopores which enhances the diffusivity of the reactant molecules during the catalytic reaction and improves dispersion of the deposited gold nanoparticles while also preventing their aggregation at the same time and (iii) the small size of the deposited gold nanoparticles (2-5 nm) which falls within the ideal size of gold nanoparticles for achieving high CO conversion.[a] S.

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Section: Introductionmentioning

confidence: 99%

Gold‐Loaded Nanoporous Iron Oxide Cubes Derived from Prussian Blue as Carbon Monoxide Oxidation Catalyst at Room Temperature

et al. 2018

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“…From the viewpoint of photocatalytic organic synthesis, if the PEC-generatedh ighly active oxygen or hydrogen species directly participates in the chemical oxidation or reduction reaction, ap romisings trategy based on PEC water-splitting/organic-synthesis coupling can be achieved. The following advantages are expected in this new reaction system:f irstly,P EC facilitates the charges eparation owingt ot he introductiono f ab ias, giving rise to high catalytic efficiency;s econdly,h ighlyactiveo xygen or hydrogen species originating from PEC water splitting serves as clean and cost-effective oxidant or reducing agent, without the consumption of noxiouso rganic counterparts.I na ddition, this PEC water-splitting/organic-synthesis coupling process may occur at normalp ressure andt emperature in aqueousm edia, so as to achieve ag reen synthesis pathway.The transformation of alcohols to corresponding aldehydes in liquid-phase oxidation has been well-developed previously by using variousc atalysts, including noble metal catalysts (e.g., Pd, Au) [31][32][33][34] and non-precious-metalc atalysts. [35,36] Differently, here we report photoelectrochemical oxidation of alcohols in the photoanode with H 2 generated in the cathode, which couples PEC water splitting with selectiveo xidation reaction of organic molecules.…”

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confidence: 99%

“…The transformation of alcohols to corresponding aldehydes in liquid-phase oxidation has been well-developed previously by using variousc atalysts, including noble metal catalysts (e.g., Pd, Au) [31][32][33][34] and non-precious-metalc atalysts. [35,36] Differently, here we report photoelectrochemical oxidation of alcohols in the photoanode with H 2 generated in the cathode, which couples PEC water splitting with selectiveo xidation reaction of organic molecules.…”

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confidence: 99%

Photoelectrochemical Catalysis toward Selective Anaerobic Oxidation of Alcohols

Zhang

Shao

et al. 2017

Chemistry A European J

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Selective oxidation of alcohols to aldehydes plays an important role in perfumery, pharmaceuticals, and agrochemicals industry. Different from traditional catalysis or photocatalytic process, here we report an effective photoelectrochemical (PEC) approach for selective anaerobic oxidation of alcohols accompanied with H production by means of solar energy. By using TiO nanowires modified with graphitic carbon layer as photoanode, benzyl alcohol (BA) has been oxidized to benzaldehyde with high efficiency and selectivity (>99 %) in aqueous media at room temperature, superior to individual electrocatalytic or photocatalytic processes. Moreover, this PEC synthesis method can be effectively extended to the oxidation of several other aryl alcohols to their corresponding aldehydes under mild conditions. The electron spin resonance (ESR) results indicate the formation of intermediate active oxygen (O ) on the photoanode, which further reacts with alcohols to produce final aldehyde compounds.

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“…[2][3][4] Among the varioust ransition-metal catalysts that have shown activity for this aerobic oxidation, those based on supported metal nano-particles (NPs) are among the most efficient and selective ones, exhibiting al arge scope under aw ide range of experimentalc onditions. [2,3,5,6] In this type of heterogeneousc atalysts, one of the most important roles of the support is to stabilize the dimensions of gold NPs, minimizing their growth by strong metal-support interactions. [2,7,8] Extensive study of the literature has shown that the catalytic activity of metal NPs for this aerobic oxidation decreases as the particles ize increases.…”

Section: Introductionmentioning

confidence: 99%

Tuning the Microenvironment of Gold Nanoparticles Encapsulated within MIL‐101(Cr) for the Selective Oxidation of Alcohols with O₂: Influence of the Amino Terephthalate Linker

Santiago‐Portillo

Cabrero-Antonino

Álvaro

et al. 2019

Chemistry A European J

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This manuscript reports a comparative study of the catalytic performance of gold nanoparticles (NPs) encapsulated within MIL‐101(Cr) with or without amino groups in the terephthalate linker. The purpose is to show how the amino groups can influence the microenvironment and catalytic stability of incorporated gold nanoparticles. The first influence of the presence of this substituent is the smaller particle size of Au NPs hosted in MIL‐101(Cr)‐NH2 (2.45±0.19 nm) compared with the parent MIL‐101(Cr)‐H (3.02±0.39 nm). Both materials are highly active to promote the aerobic alcohol oxidation and exhibit a wide substrate scope. Although both catalysts can achieve turnover numbers as high as 106 for the solvent‐free aerobic oxidation of benzyl alcohol, Au@MIL‐101(Cr)‐NH2 exhibits higher turnover frequency values (12 000 h−1) than Au@MIL‐101(Cr)‐H (6800 h−1). Au@MIL‐101(Cr)‐NH2 also exhibits higher catalytic stability, being recyclable for 20 times with coincident temporal conversion profiles, in comparison with some decay observed in the parent Au@MIL‐101(Cr)‐H. Characterization by transmission electron microscopy of the 20‐times used samples shows a very minor particle size increase in the case of Au@MIL‐101(Cr)‐NH2 (2.97±0.27 nm) in comparison with the Au@MIL‐101(Cr)‐H analog (5.32±0.72 nm). The data presented show the potential of better control of the microenvironment to improve the performance of encapsulated Au nanoparticles.

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Oxidation of Benzyl Alcohol and Carbon Monoxide Using Gold Nanoparticles Supported on MnO₂ Nanowire Microspheres

Cited by 43 publications

References 61 publications

Gold‐Loaded Nanoporous Iron Oxide Cubes Derived from Prussian Blue as Carbon Monoxide Oxidation Catalyst at Room Temperature

Gold‐Loaded Nanoporous Iron Oxide Cubes Derived from Prussian Blue as Carbon Monoxide Oxidation Catalyst at Room Temperature

Photoelectrochemical Catalysis toward Selective Anaerobic Oxidation of Alcohols

Tuning the Microenvironment of Gold Nanoparticles Encapsulated within MIL‐101(Cr) for the Selective Oxidation of Alcohols with O₂: Influence of the Amino Terephthalate Linker

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Oxidation of Benzyl Alcohol and Carbon Monoxide Using Gold Nanoparticles Supported on MnO2 Nanowire Microspheres

Cited by 43 publications

References 61 publications

Gold‐Loaded Nanoporous Iron Oxide Cubes Derived from Prussian Blue as Carbon Monoxide Oxidation Catalyst at Room Temperature

Gold‐Loaded Nanoporous Iron Oxide Cubes Derived from Prussian Blue as Carbon Monoxide Oxidation Catalyst at Room Temperature

Photoelectrochemical Catalysis toward Selective Anaerobic Oxidation of Alcohols

Tuning the Microenvironment of Gold Nanoparticles Encapsulated within MIL‐101(Cr) for the Selective Oxidation of Alcohols with O2: Influence of the Amino Terephthalate Linker

Contact Info

Product

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Oxidation of Benzyl Alcohol and Carbon Monoxide Using Gold Nanoparticles Supported on MnO₂ Nanowire Microspheres

Tuning the Microenvironment of Gold Nanoparticles Encapsulated within MIL‐101(Cr) for the Selective Oxidation of Alcohols with O₂: Influence of the Amino Terephthalate Linker